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T’was the week before Christmas, a night during Chanukah and a couple of weeks before Kwanzaa, when, all through the nation, many readers more interested in America’s energy supply than in the fate of Sony’s “The Interview,” were stirring before their non-polluting fireplaces (I wish). They were trying to grasp and relish the unique rhetorical battle between The University of Texas (UT), the EIA and the recent December article in Nature, titled “Natural Gas: The Fracking Fallacy,” by Mason Inman.

Let me summarize the written charges and counter charges between a respected journal, university and government agency concerning the article. It was unusual, at times personal and often seemingly impolite.

Unusual, since a high-ranking federal official in the EIA responded directly to the article in Nature, a well-thought of journal with an important audience, but relatively minimal circulation. His response was, assumedly, based on a still-unfinished study by a group of UT scholars going through an academic peer review process. The response was not genteel; indeed, it was quite rough and tough.

Clearly, the stakes were high, both in terms of ego and substance. As described in Nature, the emerging study was very critical of EIA forecasts of natural gas reserves. Assumedly EIA officials were afraid the article, which they believed contained multiple errors and could sully the agency’s reputation. On the other hand, if it was correct, the UT authors would be converted into courageous, 21st century versions of Diogenes, searching for energy truths. The article would win something like The Pulitzer, EIA would be reprimanded by Congress and the UT folks would secure a raise and become big money consultants to a scared oil and gas industry.

Just what did the Nature article say? Succinctly: The EIA has screwed up. Its forecasts over-estimate America’s natural gas reserves by a significant amount. It granted too much weight to the impact of fracking and not enough precision to its analysis of shale play areas as well as provide in-depth resolution and examination of the sub areas in major shale plays. Further, in a coup de grace, the author of the Nature piece apparently, based on his read of the UT study, faults the EIA for “requiring” or generally placing more wells in non-sweet-spot areas, therefore calculating more wells than will be developed by producers in light of high costs and relatively low yields. Succinctly, the EIA is much too optimistic about natural gas production through 2040. UT, according to Nature, suggests that growth will rise slowly until early in the next decade and then begin to decline afterwards through at least 2030 and probably beyond.

Neither Wall Street nor producers have reacted in a major way to the Nature article and the still (apparently) incomplete UT analysis. No jumping out of windows! No pulling out hairs! Whatever contraction is now being considered by the industry results from consideration of natural gas prices, the value of the dollar, consumer demand, the slow growth of the economy and surpluses.

Several so-called experts have responded to the study in the Journal piece. Tad Patzek, head of the UT Austin department of petroleum and geosystems, engineers and “a member of the team,” according to the Journal, indicated that the results are “bad news.” The push to extract shale gas quickly and export, given UT’s numbers, suggests that “we are setting ourselves up for a major fiasco.” Economist and Professor Paul Stevens from Chatham House, an international think tank, opines “if it begins to look as if it’s going to end in tears in the U.S., that would certainly have an impact on the enthusiasm (for exports) in different parts of the word.”

Now, generally, a bit over the top, provocative article in a journal like Nature commending someone else’s work would have the author of the article and UT principal investigators jumping with joy. The UT researchers would have visions of more grants and, if relevant, tenure at the University. The author would ask for possible long-term or permanent employment at Nature or, gosh, maybe even the NY Times. Alas, not to happen! The UT investigators joined with the EIA in rather angry, institutional and personal responses to the Journal. Both the EIA and UT accused Nature of intentionally “misconstruing data and “inaccurate…distorted reporting.”

Clearly, from the non-scholarly language, both institutions and their very senior involved personnel didn’t like the article or accompanying editorial in Nature. EIA’s Deputy Administrator said that the battle of forecasts between the EIA and UT, pictured in the Journal, was imagined and took both EIA’s and UT’s initiatives out of context. He went on to indicate that both EIA’s and UT efforts are complementary, and faulted Nature for not realizing that EIA’s work reflected national projections and UT’s only four plays. Importantly, the Deputy suggested that beyond area size and method of counting productivity, lots of other factors like well spacing, drilling costs, prices and shared infrastructure effect production. They were not mentioned as context or variables in the article.

The principal investigators from UT indicated that positing a conflict between the EIA and themselves was just wrong. “The EIA result is, in fact, one possible outcome of our model,” they said. The Journal author “misleads readers by suggesting faults in the EIA results without providing discussion on the importance of input assumptions and output scenarios. “Further, the EIA results were not forecasts but reference case projections. The author used the Texas study, knowing it was not yet finished, both as to design and peer review. Adding assumed insult to injury, it quoted a person from UT, Professor Patzek, more times than any other. Yet, he was only involved minimally in the study and he, according to the EIA, has been and is a supporter of peak oil concepts, thus subject to intellectual conflict of interests.

Nature, after receiving the criticism from UT and EIA, stood its ground. It asserted that it combined data and commentary from the study with interviews of UT personal associated with the study. It asked for but only received one scenario on gas plays by EIA — the reference case. It was not the sinner but the sinned against.

Wow! The public dialogue between UT, the EIA and Nature related to the article was intense and, as noted earlier, unusual in the rarefied academically and politically correct atmosphere of a university, a federal agency and a “scientific” journal. But, to the participants’ credit, their willingness to tough it out served to highlight the difficulty in making forecasts of shale gas reserves, in light of the multitude of land use, geotechnical, economic, environmental, community and market variables involved. While it is not necessary or easy to choose winners or losers in the dialogue, because of its “mince no words” character, it, hopefully, will permit the country, as a whole, to ultimately win and develop a methodology to estimate reserves in a strategic manner. This would be in the public interest as the nation and its private sector considers expanding the use of natural gas in transportation, converting remaining coal-fired utilities to environmentally more friendly gas-powered ones and relaxing rules regulating natural gas exports. We remain relying on guesstimates concerning both supply and demand projections. Not a good place to be in when the stakes are relatively high with respect to the health and well-being of the nation.

On a personal note, the author of the article in Nature blamed, in part, the EIA’s inadequate budget for what he suggested were the inadequacies of the EIA’s analysis. Surprise, given what the media has often reported as the budget imperialism of senior federal officials, the Deputy Administrator of EIA, in effect, said hell no, we had and have the funds needed to produce a solid set of analyses and numbers, and we did. Whether we agree with his judgments or not, I found his stance on his budget refreshing and counterintuitive.

At the base rate, the U.S. military pays about the same as the rest of us for gasoline, under $3 a gallon. But the costs quickly escalate when you factor in the expenses related to getting fuel where it needs to go, and the often rugged, isolated places American forces need to use their vehicles.

… paying 100 times the price the rest of us are. The total cost of getting fuel where it needs to be is skyrocketing the cost for military gas. At a burn rate of 300,000 barrels of oil per day, the Department of Defense consumes 1.5 percent of total national consumption, and is the largest user of energy in America. As a result, it is the biggest proponent of clean energy. Even a total cost of $100 per gallon would be a steal for the military. That’s because its calculations on energy costs are very different than for a regular consumer.

It makes sense, therefore, that the U.S. Defense Department is far ahead the game when it comes to pursuing alternative fuel sources:

Some current projects include a way to produce localized energy on site, creating a mobile energy system and better integrating generators and batteries. There are dozens of projects already underway at military bases globally and multi-decade, long-term plans to find efficiency. Some of the projects include focusing on green power, renewable jet fuels and changing the culture around energy awareness in day-to-day operations.

Lane Kelley of ICIS Chemical Business calls it “methanol mania” and he probably wasn’t exaggerating. Last week Texas and Louisiana underwent an explosion of activity, promising to turn the region into a world center for methanol.

Earlier this month, Louisiana Gov. Bobby Jindal announced that Castleton Commodities International LLC (CCI), a Connecticut firm, will be building a $1.2 billion methanol manufacturing plant on the Mississippi River in Plaquemines Parish. The plant is expected to produce $1.8 million tons of methanol a year.

“This plant will help our children stay in Louisiana instead of leaving the state to find jobs,” said Jindal. “My number one priority it to make Louisiana a business friendly place.”

But that’s not even half of it. The Environmental Protection Administration (EPA) just gave its final approval to a $1 billion methanol plant to be built near Beaumont, Texas. The facility will be operated by Natgasoline LLC, a subsidiary of a Netherlands-based company that already employs 72,000 people in 35 countries. It will employ thousands of construction workers and carry a $20 million payroll when it begins operating in of 2016.

Does that sound like a lot? Well, don’t forget Methanex Corporation, the country’s largest manufacturer of methanol, is in the process of moving two plants back from Chile to Louisiana. One plant is scheduled to open in a few months. And ZEEP (Zero Emissions Energy Plants), an Austin-based company, has just raised $1 million for a proposed plant in St. James Parish, La.

Does that sound like a full plate? Well, it’s still just the beginning. The Connell Group, a government-supported operation, announced long-range plans for what would be the largest methanol plant in the world — even if only half it gets built. The first unit, located in either Texas or Louisiana, would produce 3.6 million tons a year, twice the current world record holder in Trinidad. Together, the two units would produce more than the current U.S. demand, 6.3 million tons a year. The term “Gigafactory” soon may be standard vocabulary.

So what’s going on? Well, the plan is for nearly all this Texas and Louisiana methanol production to be exported to China. The widening of the Panama Canal for supertankers, scheduled to be completed in early 2016, will be a bit part of the puzzle. Believe it or not, China also has plans to build three more plants in Oregon and Washington. But they run into trouble there, of the West Coast’s dislike of fossil fuels.

So China is planning to use American natural gas as a substitute for its own coal, in producing large amounts of methanol. It’s no different from the Chinese buying up farmland in Brazil and Ukraine in order to grow crops.

But the Chinese have other things in mind as well. Zhejiang Geely Holding Group Co., Ltd, Chery International, Shanghai Maple Guorun Automobile Co., Ltd. and Shanghai Automotive Industry Corp. all produce methanol-adaptive cars, which now accounts for eight percent of China’s fuel consumption. Israel is also experimenting with methanol from natural gas as a substitute for imported oil.

Methanol produces only 50 percent of the energy of gasoline, but its higher octane rating brings it up into the 65 percent range. It produces 40 percent less carbon dioxide and other pollutants and would go a long way toward helping China improve its pollution problems. As far as methanol production is concerned, China sees only see an upside.

So what’s going on in this country? Well, so far we have the world’s largest reserves of natural gas, we are on the verge of becoming a world center methanol manufacturer — yet we still have a set of rules and regulations and sheer inertia that prevent us from powering our cars with methanol. For some strange reason, the United States is about to become a world center for the production of methanol, yet we still haven’t figured out how to put it to one of its best uses.

The U.S. energy problem is very much due to a breakdown of the free market, contends the new documentary, “Pump.” Married co-directors Josh Tickell and Rebecca Harrell Tickell show how Big Oil’s monopoly on transportation fuels hurts Americans more than they realize. If drivers had options when filling up their tanks, both country and consumers would benefit.

I’m looking forward to checking out Pump because believe it or not I think the subject of clean energy and renewable energy is important especially with our gas guzzling cars! Here’s some character posters along with the trailer for the documentary.

PUMP is an inspiring, eye-opening documentary that tells the story of America’s addiction to oil, from its corporate conspiracy beginnings to its current monopoly today, and explains clearly and simply how we can end it – and finally win choice at the pump.

PUMP is an inspiring, eye-opening documentary that tells the story of America’s addiction to oil, from its corporate pump 2conspiracy beginnings to its current monopoly today, and explains clearly and simply how we can end it – and finally win choice at the pump.

Some time in the future–perhaps a decade from now–we’ll all be driving around in electric cars (probably). Battery technology will have evolved to allow longer trips on a single charge, and they’ll be significantly cheaper than they are now.

A decade from now, though? That’s a long way off. In meantime, we’re going to need other ways to reduce our dependence on oil–both because oil increases instability in the world (look at Russia’s current oil-fueled adventures) and because it contributes to climate change, a problem that really can’t wait.

In 1962, German researcher Hanns-Peter Boehm suggested the versatile carbon atom, which can form long chains, might be configured into a chicken-wire pattern to create a stable molecule one atom thick.

The idea remained a theoretical construct without even a name until 1987, when researchers started calling it “graphene.” Basically, graphene is two-dimensional graphite, the pure carbon material that makes up “lead” pencils. The term was also used to describe the carbon nanotubes that were beginning to attract attention for their ultra-solid properties. For a while there was talk of elevators reaching up into space until it became clear that creating nanotubes without impurities that degrade their properties was currently out of the reach of mass production.

Then in 2004, Andre Geim and Kostya Novoselov, two researchers at The University of Manchester, came up with something a little more prosaic. They applied Scotch tape – yes, ordinary Scotch tape – to pure graphite and found they could peel off the single layer of carbon in the chicken-wire pattern that Boehm had described. They called this substance “graphene” and were awarded the Nobel Prize in 2010.

The discovery of single-layer graphene has set off a stampede into research of its properties. Carbon is, after all, a versatile element, the basic building block of life that can also be packed into a material as hard as a diamond, which is also pure carbon. When stretched out into lattices a million times thinner than a human hair, however, it has the following remarkable properties:

It is the strongest material ever discovered, 300 times stronger than steel.

It is the most electrically conductive material ever discovered, 1,000 times more conductive than silicon.

It is the most thermally conductive material ever discovered.

It is bendable, shapeable and foldable.

It is completely transparent, although it does filter some light.

In short, graphene is now being touted as “material of the 21st century,” the substance that could bring us into an entirely new world of consumer products, such as cell phones that could be sewn into our clothes.

All this still remained somewhat theoretical, since no one had been able to produce graphene in dimensions larger than single tiny crystals. When these crystals were joined together, they lost most of their properties. Two weeks ago, however, Samsung announced that it has been able to grow a graphene crystal to the size of a wafer, somewhat on the same dimensions as the silicon wafers that produce computer chips. Thus, the first step toward a new world of electronics may be upon us. Graphene cannot be used as a semiconductor, since it is always “on” in conducing electricity, but combined with other substances it may be able to replace silicon, which is many researches believe is currently reaching its physical limits.

So what does this mean for the world of transportation, where we are always looking for new ways to construct automobiles and find alternative power sources to substitute for our gas tanks? Well, plenty.

Most obvious is the possibility of making cars out of much lighter-weight materials to reduce the power burden on engines. Chinese researchers recently came up with a graphene aerogel that is seven times lighter than air. A layer spread across 28 football fields would weigh only one ounce and a cubic inch of the material would balance on a blade of grass. All this would occur while it still retained its 300-times-stronger-than-steel properties. Graphene itself would not be used to construct cars, but it could be layered with other materials.

But the most promising aspect of graphene may be in the improvement of batteries. Lithium-ion batteries achieve an energy density of 200 Watt-hours-per-kilogram, which is five times the 40-Wh/k density of traditionally lead-acid batteries. That has won it the prime role in consumer electronics. But Li-ion batteries degrade over time, which is not a problem for a cell phone, but becomes prohibitive when the battery must undergo more than 1,000 charge cycles and is half the price of the car.

Lithium-sulfur batteries have long been thought to hold promise but they, too, deteriorate quickly, sometimes after only a few dozen charges. But recently, researchers at Lawrence Berkeley Labs in California modified a lithium sulfur battery by adding sandwiched layers of a graphene. The result is a battery that achieves 400 Wh/k – double the density of plain lithium-ion – and has gone through 1,500 charging cycles without deterioration. This would give an electric car a range of more than 300 miles, which is in the lower range of what can be achieved with the internal combustion engine.

And so the effort to improve electric vehicles is moving forward, sometimes on things coming out of left field. If graphene really proves to be a miracle substance, look for Elon Musk to be discussing its wonders as he prepares to build that “megafactory” that is supposed to produce lithium-ion batteries capable of powering an affordable new version of the Tesla.

The decision isn’t scheduled until June but already opposing sides are converging on Washington, trying to pressure the Environmental Protection Agency over the 2014 Renewable Fuel Standard for ethanol.

Last week almost 100 members of the American Coalition for Ethanol descended on the nation’s capital for its annual “Biofuels Beltway March,” buttonholing 170 lawmakers and staffers from 45 states. The object was to send a message to EPA Administrators Gina McCarthy to up the ante on how many billions of gallons the oil refining industry will be required to purchase this year.

The ethanol program is currently in turmoil. The latest problem is rail bottlenecks that have slowed shipments and created supply shortages over the winter months. Record-breaking cold and four-foot snow pack have been partly responsible but the rail lines are also becoming overcrowded. With all that oil gushing down from the Bakken and Canadian crude now finding its way into tank cars as the Obama Administration postpones its decision over the Keystone Pipeline, ethanol is getting tangled in traffic. .

“Ethanol for April delivery sold for about $3.02 a gallon on the Chico Board of Trade, an 81 percent increase over the low price during the past 12 months of $1.67 a gallon reached in November,” reported the Omaha World-Herald last Friday“This weeks settlement price of $2.98 a gallon was the highest since July 2011.” With only so much storage capacity, some ethanol refineries have been forced to shut down until the next train arrives to carry off the inventory. As ethanol becomes mainstream, it is becoming more and more subject to market events beyond its control.

But the big decision will be EPA’s ruling in June. In accord with the 2008 Renewable Fuel Act, Administrator McCarthy must set a “floor” for amount of ethanol refiners will have to incorporate into their blends during 2014. The program ran into trouble last year when the 13.8 billion gallon requirement pushed ethanol beyond the 10 percent “blend wall” where the auto companies will not honor warrantees in older cars. Refiners were forced to purchase compensating Renewable Identification Numbers (RINs), which exploded in value from pennies to $1.30 per gallon, forcing up the price of gasoline. Contrary to expectations, gasoline consumption has actually declined over the last six years, from 142 billion gallons in 2008 to 134 billion in 2013 as a result of mileage improvements plus the lingering effects of the recession. Last November McCarthy proposed reducing the 2014 from 14.4 billion gallons to 13 billion. The industry has been crying “foul” ever since.

But there are other ways to fight back. Last week in Crookson, gas stations were offering Minnesota drivers 85 cents off a gallon for filling up with E-85, the blend of 85 percent ethanol that many see as the real solution to the blend-wall problem. “We want the public to understand there are different ratios of gasoline and ethanol and how they can save you money,” Greg LeBlac, of the Polk County Corn Growers, told the Fargo Valley News.

At the annual meeting of the American Fuel and Petroleum Manufacturers (APFM) in Orlando last week, Anna Temple, product manager at WoodMac, made the case that the industry should forego efforts to raise the blend wall from 10 to 15 percent and instead shoot for the moon, leapfrogging all the way to E-85, where ethanol essentially replaces gasoline completely. (The 15 percent only ensures starts in cold weather.)

“E-15 is a non-starter in terms of market share,” Temple told her audience, as reported by John Kingston’s in Platts.http://blogs.platts.com/2014/03/25/eight-fillups/ She argued the incremental battle would absorb vast amounts of political capital yet still not be enough to absorb the 15-billion-gallon target for 2021. Instead, Temple pointed to the growing fleet of flex-fuel vehicles that now numbers around 15 million, headed for 25 million in 2021 or 10 percent of the nation’s 250-million-car fleet.

“If U.S. drivers poured about 200,000 barrels-per-day of E-85 into their flex fuel cars in 2021, that would take care of about 17 percent of the scheduled ethanol mandate,” Temple said. “It would only require that flex-fuel owners fill a 15-gallon tank eight times a year.” The remainder would be absorbed in the 10 percent blend and ethanol producers would not have to cut output.

Platts’ Kingston checked the math and found that even this goal would leave ethanol consumption slightly above the blend wall at 10.5 percent. “Still, the very modest number of eight fill-ups per flex fuel vehicles per year makes the whole blend wall issue seems a lot less daunting,” he confessed.

Of the 15 million people who own flex-fuel vehicles, of course, many don’t even realize it. (The yellow gas cap or a rear-end decal are the giveaway.) But the number of gas stations offering E-85 pumps is rising. The Energy Information Administration now estimates the number at 2,500 with most of the growth taking place outside the Midwestern homeland. California and New York each have more than 80 stations apiece.

The problem of rail bottlenecks can probably be solved by increasing the number of E-85 outlets and flex-fuel vehicles to bring supplies closer to the place of consumption. Still, the industry would probably be happy to have a bigger renewable fuel mandate as well.